CN102360502A - Automatic baseline correction method - Google Patents

Abstract

The invention discloses an automatic baseline correction method, which includes the following steps: converting raw data into spectrogram data; utilizing continuous wavelet transform to calculate the numerical derivative of a spectrogram; respectively utilizing the sliding window method and the iterative threshold method to identify narrow peak signals and broad peak signals in the spectrogram; carrying out contour fitting on the broad peak signals to identify the edges of the broad peak signals; calculating a baseline model; correcting the spectrogram data according to the baseline model; searching distorted signals in the corrected spectrogram data, and recalculating the baseline model with the most severely distorted points as baseline points until distorted signals do not exist, so that a final baseline model and final corrected spectrogram data can be obtained. Compared with the prior art, the automatic baseline correction method can eliminate the inaccuracy of noise calculation caused by baseline distortion, accurately identify the narrow peak signals and the broad peak signals in the spectrogram, correct the spectrogram with the severely distorted baseline and prevent spectral peak distortion introduced into the complex spectrogram by baseline correction.

Description

A kind of automatic baseline correction method

Technical field

The present invention relates to the spectrum analysis field, more specifically relate to a kind of automatic baseline correction method.Be applicable to nuclear magnetic resoance spectrum, chromatogram, the analysis of various spectrograms such as Raman spectrum and late time data are handled.

Background technology

Baseline distortion meeting makes a big impact to spectrum elucidation and spectrogram quantitative test, and eliminating the baseline distortion is the steps necessary that the spectrogram late time data is handled.Present widely used baseline correction algorithm all is a frequency domain baseline correction method.Its principle is on the basis of spectral data, to construct a smooth base model, thereby deducts the spectral data that this baseline model obtains not having distortion by original spectral data then.

General frequency domain baseline correction method is on the baseline point that identifies, to make up baseline model.Than the baseline correction algorithm that does not have baseline identification, there is the algorithm of baseline identification can handle the situation that there is posivtive spike in baseline distortion in the spectrogram more greatly and not only but also has negative peak, so it is more suitable for various analysis of spectra.Dietrich had proposed on the basis of spectrogram numerical derivative, to utilize the algorithm of repetition threshold value iteration to discern baseline in 1991.Thereby Cobas utilizes continuous wavelet transform to replace numerical derivative to calculate and has improved this algorithm.Golotvin had proposed another kind of baseline recognition methods in 2000, and we are referred to as the moving window method at this.All there are different separately relative merits in above-mentioned baseline recognition methods, as on the basis of spectrogram numerical derivative, carrying out baseline identification, can reduce signal to noise ratio (S/N ratio) and can make the broad peak blackout in the spectrogram; Can solve the problem that signal to noise ratio (S/N ratio) reduces after adopting continuous wavelet transform to improve, but need artificial adjustment parameter could discern the broad peak signal; It is not accurate enough to the identification at spectrum edge, peak that we find to utilize the iteration threshold method in the process of this external practical application, and the moving window method is not accurate enough even can not identify to the identification of the broad peak signal in the spectrogram.

On the basis of the baseline that identifies, making up suitable baseline model is second step in the baseline correction, also is the most key step.The various model building methods that exist at present can be divided into two types: the first kind is the baseline point that utilizes certain functions to come match to identify, like fitting of a polynomial, and cubic spline interpolation etc.; Second type is on the baseline that identifies, to utilize smoothing algorithm such as Whittaker filtering etc. to make up baseline model.Utilize certain functions to come the match baseline model can not be adapted to the bigger spectrogram of a lot of baseline distortions, do not satisfy the certain functions shape because the baseline distortion possibly be an arbitrary shape.Whittaker filtering is a kind of more effective smoothing algorithm, and peak-to-peak signal distorts but it may make spectrum in the dealing with complicated data.

Summary of the invention

The objective of the invention is the problems referred to above to existing technology existence; A kind of automatic baseline correction method is provided; This method data processing speed is fast, and it is inaccurate to eliminate the noise calculation that causes owing to the baseline distortion, and the peak distortion of having avoided baseline correction to introduce.

To achieve these goals, the present invention adopts following technical scheme:

A kind of automatic baseline correction method may further comprise the steps:

Step 1, the raw data of utilizing Fourier transform and phase correction processing collected to arrive obtain spectral data;

Step 2, utilize continuous wavelet transform that spectral data is calculated, obtain the numerical derivative of spectrogram;

Step 3, utilize the narrow peak-to-peak signal in the numerical derivative identification spectrogram of moving window method and spectrogram, it is interval to obtain narrow peak-to-peak signal;

Step 4, utilize the broad peak signal in the iteration threshold method identification spectral data, obtain part broad peak signal spacing;

Step 5, according to part broad peak signal spacing, utilize the profile approximating method to simulate the profile of broad peak signal;

Step 6, with in the spectral data greater than the point of the profile maximal value 3% of broad peak signal in the step 4 all as the broad peak signaling point, thereby obtain complete broad peak signal spacing;

Step 7, spectral data is deducted the interval and complete broad peak signal spacing of narrow peak-to-peak signal, and to obtain the baseline of spectrogram interval;

Step 8, utilize the interval initializes weights array of the baseline that the obtains w (S (m-1) of step 7 _i), if the spectral data point is positioned at the signal spacing, then the weight array value is initialized as 0, if the spectral data point is positioned at the baseline interval, then the weight array value is initialized as 1;

Step 9, utilize weight array and filtering algorithm to calculate baseline model;

Step 10, utilize the baseline model in the step 9 the described spectral data of step 1 to be proofreaied and correct the spectral data after obtaining proofreading and correct;

Step 11, each spectrum peak in the spectral data after judge proofreading and correct one by one; If the appearance of negative fractional part thinks that then this spectrum peak has produced distortion in the positive spike; If positive fractional part occurred in the negative spike; Think that then this spectrum peak produces distortion, distort then execution in step 12, withdraw from the spectral data after calculating final baseline model and proofreading and correct if the spectrum peak does not produce distortion if the spectrum peak produces;

Step 12, spectrum peak in the step 11 is produced the most serious some setting of the distortion baseline point that is as the criterion;

The weight array that accurate baseline point in step 13, the step 12 is corresponding is set to 1 and return step 9 and recomputate baseline model.

Utilize the moving window method may further comprise the steps in the aforesaid step 3:

Step 3.1, according to the spectral data derivative calculations noise level σ that obtains in the step 2 _Noise

Step 3.2, setting threshold are n * σ _Noise, wherein n is a parameter value;

The size of step 3.3, the threshold value relatively confirmed in height and the step 3.2 of moving window, if the height of moving window greater than threshold value, then the central point of moving window is positioned at narrow peak-to-peak signal interval; If the height of moving window is smaller or equal to threshold value, then the central point of moving window is positioned at the baseline interval.

The iteration threshold method may further comprise the steps in the aforesaid step 4:

Step 4.1, utilize spectral data to calculate iteration threshold, iteration threshold is based on formula MEAN+3*SDEV, and MEAN is the mean value of spectral data, and SDEV is the standard deviation of spectral data;

Step 4.2, spectral data and iteration threshold are compared,, then carry out step 4.3 if there be the data point bigger than iteration threshold in spectral data; If points all in the spectral data then stop iteration all less than iteration threshold, obtain all broad peak signals, thereby obtain part broad peak signal spacing;

Step 4.3, spectral data that the ratio iteration threshold that obtains in the step 4.2 is big be as the broad peak signaling point, than the little spectral data of iteration threshold as the spectral data in the step 4.1 and return step 4.1.

Parameter value n is 3 in the aforesaid step 3.2, in the described step 3.3 length of moving window be whole spectral data width 0.2%.

Profile match in the aforesaid step 5 is based on and minimizes penalty P:

$P=\underset{\mathrm{\Ω}}{\mathrm{\Σ}}P\left(\mathrm{\Ω}\right)$

Wherein: as E (Ω)-S (Ω)>=0, P (Ω)=(E (Ω)-S (Ω)) ²As E (Ω)-S (Ω)≤0, P (Ω)=(f * (E (Ω)-S (Ω))) ², E (Ω) is the broad peak signal that needs match, and S (Ω) is the spectrum peak-to-peak signal, and f is a profile adjustment parameter, and Ω is the spectrogram frequency coordinate.

Filtering algorithm in the aforesaid step 9 is based on minimizing self-defined objective function:

$F\left(m\right)=\underset{i=1}{\overset{N}{\mathrm{\Σ}}}w{\left(S{(m-1)}_i\right)\×({S(m-1)}_i-\mathrm{\τ}{\left(m\right)}_i)}^2+$

$\mathrm{\λ}\underset{i=2}{\overset{N-1}{\mathrm{\Σ}}}{\left\{\right[\mathrm{\τ}{\left(m\right)}_{i+1}-\mathrm{\τ}{\left(m\right)}_i]-[\mathrm{\τ}{\left(m\right)}_i-\mathrm{\τ}{\left(m\right)}_{i-1}\left]\right\}}^2$

In the formula: m is meant iteration the m time, i=1, and 2 ..., N, N represent spectral data length, the baseline model data of the m time required calculating of iteration of τ (m) expression, S (m-1) _iBe the spectral data of baseline correction after the m-1 time iteration, w (S (m-1) _i) once proofread and correct the spectrogram weight array that the back spectrogram calculates before being based on, as S (m-1) _iWhen being signaling point, w (S (m-1) _i)=0; As S (m-1) _iWhen being noise spot, w (S (m-1) _i)=1.

First baseline model that requires each iterative computation to come out of objective function F (m) must loyally be proofreaied and correct back spectrogram S (m-1) in the last time _iBaseline point.Second requires each baseline model data of calculating necessary enough level and smooth.

Aforesaid a kind of automatic baseline correction method has mainly combined continuous wavelet transform, and iteration threshold method and moving window method are carried out baseline identification, and to wherein separately weak point carried out rational improvement.Utilize the numerical derivative of continuous wavelet change calculations spectrogram, purpose is that to eliminate the noise calculation cause owing to the baseline distortion inaccurate, on the basis of spectral data derivative, utilizes the moving window method to carry out baseline then and discerns.The ultimate principle of sliding window algorithm is the height and the noise level of comparison moving window, if the height of moving window is thought that then the central point of window is narrow peak-to-peak signal point, otherwise is baseline point greater than according to the noise level preset threshold.Threshold setting is that noise level multiply by a coefficient value (n σ _Noise), moving window length is taken as 0.2% of whole spectrum width generally speaking, and the coefficient value n of threshold calculations gets 3 and can meet the demands.

The moving window method can accurate recognition go out the narrow peak-to-peak signal in the spectrogram, has then adopted the iteration threshold method to combine the match of broad peak profile to discern to the broad peak signal.The iteration threshold algorithm at first utilizes all data computation to go out a threshold value (MEAN+3*SDEV; Here MEAN refers to the mean value of data; SDEV refers to the standard deviation of data); Utilize the data point littler to recomputate new iteration threshold then, all stop iteration less than iteration threshold up to remaining point than last iteration threshold.The remaining at last point littler than last iteration threshold is baseline point.Common iteration threshold algorithm is not accurate enough to the identification of spectrum tail of the peak portion, especially to the afterbody of broad peak signal.For this has carried out certain improvement to it, the method for employing is to utilize the spectrum peak profile that simulates to confirm that baseline is interval.The data fitting of at first utilizing iteration threshold to identify goes out to compose the peak profile, utilizes spectrum peak profile to confirm that baseline is interval then.The function of spectrum peak profile match has adopted the Tsallis curve, and the shape of this curve is exactly the Gaussian curve by parameter q decision (q＞1) when q value convergence 1, is Lauren thatch curve when q=2.The profile fit method has adopted the method that minimizes penalty P.

In the aforesaid step 9, the baseline point that when making up baseline model, has not only utilized 1～5 step to identify, and consider the peak distortion that in baseline process, possibly cause, avoid this distortion through continuous identification " accurate baseline point ".

Compared with prior art, advantage of the present invention and beneficial effect are:

1, it is inaccurate to eliminate the noise calculation that causes owing to the baseline distortion, the inaccurate result that will directly influence baseline identification of noise calculation, thereby the baseline correction result who makes the mistake.

2, can accurate recognition go out narrow peak-to-peak signal and broad peak signal in the spectrogram.Especially to the identification of broad peak, common algorithm can only identify part broad peak signal or can not identify the broad peak signal, thereby causes spectrogram broad peak signal after the baseline correction to diminish or disappear.After utilizing existing two kinds of baseline recognition methodss to proofread and correct in as shown in Figure 3, the broad peak signal area in the spectrogram has dwindled 64% and perhaps directly has been eliminated, and the baseline recognition methods of utilization of the present invention has kept 98% of original peak area.

3, can the bigger spectrogram of check baseline distortion.

4, can avoid in complicated spectrogram since baseline correction introduce the distortion of spectrum peak.In as shown in Figure 4; Utilize the spectrogram after existing method is proofreaied and correct all to produce distortion to a certain degree; This distortion directly influences the integral area of spectrogram; Existing various baseline correction method has caused 10%～26% error to this spectrogram part signal integral area, and the integral area value remains on 98% after adopting new method to carry out baseline correction.

Description of drawings

Fig. 1 is a baseline recognition methods process flow diagram in a kind of automatic baseline correction method.

Fig. 2 is a baseline model construction method process flow diagram in a kind of automatic baseline correction method.

Fig. 3 adopts relatively synoptic diagram of different baseline recognition methods effects in the baseline correction method.

(a) original match NMR spectral data wherein; (b) continuous wavelet transform combines the moving window method to carry out baseline identification; (c) on the b basis, add common iteration threshold method and carry out broad peak identification; (d) method that this paper proposes has been adopted in baseline identification.

Fig. 4 adopts diverse ways to carry out the baseline correction result when being the baseline model structure and contrasts synoptic diagram.

(a) original metabolism group NMR spectral data wherein; (b) utilize polynomial fitting method to carry out baseline correction; (c) utilize Whittaker filtering to carry out baseline correction; (d) utilize Hodrick-Prescott filtering to carry out baseline correction; (e) utilize the baseline correction method that adopts among the present invention.

Embodiment

Below in conjunction with accompanying drawing, technical scheme of the present invention is done further to describe in detail.

Embodiment 1:

Like Fig. 1, shown in Figure 2, a kind of automatic baseline correction method may further comprise the steps:

Step 1 (input spectrum diagram data 1), the raw data of utilizing Fourier transform and phase correction processing collected to arrive obtain spectral data;

Step 2 (carrying out continuous wavelet transform 2), utilize continuous wavelet transform that spectral data is calculated, obtain the numerical derivative of spectrogram;

Step 3 (utilizing moving window to discern narrow peak-to-peak signal 3), utilize the narrow peak-to-peak signal in the numerical derivative identification spectrogram of moving window method and spectrogram, it is interval to obtain narrow peak-to-peak signal;

Step 4 (utilizing iteration threshold method identification broad peak signal 4), utilize the broad peak signal in the iteration threshold method identification spectral data, obtain part broad peak signal spacing;

Step 5 (the broad peak signal is carried out profile match 5), according to part broad peak signal spacing, utilize the profile approximating method to simulate the profile of broad peak signal;

Step 6 (calculating complete broad peak signal spacing 6), with in the spectral data greater than the point of the profile maximal value 3% of broad peak signal in the step 4 all as the broad peak signaling point, thereby obtain complete broad peak signal spacing;

Step 7 (obtaining the baseline interval 7 of spectrogram), spectral data is deducted the interval and complete broad peak signal spacing of narrow peak-to-peak signal, and to obtain the baseline of spectrogram interval;

Step 8 (initializes weights array 8), utilize the interval initializes weights array of the baseline that obtains of step 7, if the spectral data point is positioned at the signal spacing, then the weight array value is initialized as 0, if the spectral data point is positioned at the baseline interval, then the weight array value is initialized as 1;

Step 9 (calculate baseline model 9), utilize weight array and filtering algorithm to calculate baseline model;

Step 10 (baseline correction 10), utilize the baseline model in the step 9 the described spectral data of step 1 to be proofreaied and correct the spectral data after obtaining proofreading and correct;

Step 11 (judging whether exist in the spectrogram), judge each spectrum peak in the spectral data after proofreading and correct one by one because the distortion 11 that baseline correction is introduced; If the appearance of negative fractional part thinks that then this spectrum peak has produced distortion in the positive spike; If positive fractional part occurred in the negative spike; Think that then this spectrum peak produces distortion, distort then execution in step 12, withdraw from the spectral data after calculating final baseline model and proofreading and correct if the spectrum peak does not produce distortion if the spectrum peak produces;

Step 12 (finding out " accurate baseline point " 12), spectrum peak in the step 11 is produced the most serious some setting of the distortion baseline point that is as the criterion according to distortion;

The weight array that accurate baseline point in step 13 (power of amendment tuple group 13), the step 12 is corresponding is set to 1 and return step 9 and recomputate baseline model.

Utilize the moving window method may further comprise the steps in the step 3:

Step 3.1, according to the spectral data derivative calculations noise level σ that obtains in the step 2 _Noise

Step 3.2, setting threshold are n * σ _Noise, wherein n is a parameter value;

The size of step 3.3, the threshold value relatively confirmed in height and the step 3.2 of moving window, if the height of moving window greater than threshold value, then the central point of moving window is positioned at narrow peak-to-peak signal interval; If the height of moving window is smaller or equal to threshold value, then the central point of moving window is positioned at the baseline interval.

The iteration threshold method may further comprise the steps in the step 4:

Step 4.1, utilize spectral data to calculate iteration threshold, iteration threshold is based on formula MEAN+3*SDEV, and MEAN is the mean value of spectral data, and SDEV is the standard deviation of spectral data;

Step 4.2, spectral data and iteration threshold are compared,, then carry out step 4.3 if there be the data point bigger than iteration threshold in spectral data; If points all in the spectral data then stop iteration all less than iteration threshold, obtain all broad peak signals, thereby obtain part broad peak signal spacing;

Step 4.3, spectral data that the ratio iteration threshold that obtains in the step 4.2 is big be as the broad peak signaling point, than the little spectral data of iteration threshold as the spectral data in the step 4.1 and return step 4.1.

Parameter value n is 3 in the step 3.2, in the described step 3.3 length of moving window be whole spectral data width 0.2%.

Profile match in the step 5 is based on and minimizes penalty P:

$P=\underset{\mathrm{\Ω}}{\mathrm{\Σ}}P\left(\mathrm{\Ω}\right)$

Wherein: as E (Ω)-S (Ω)>=0, P (Ω)=(E (Ω)-S (Ω)) ²As E (Ω)-S (Ω)≤0, P (Ω)=(f * (E (Ω)-S (Ω))) ², E (Ω) is the broad peak signal that needs match, and S (Ω) is the spectrum peak-to-peak signal, and f is a profile adjustment parameter, and Ω is the spectrogram frequency coordinate.

Filtering algorithm in the step 9 is based on minimizing self-defined objective function:

$F\left(m\right)=\underset{i=1}{\overset{N}{\mathrm{\Σ}}}w{\left(S{(m-1)}_i\right)\×({S(m-1)}_i-\mathrm{\τ}{\left(m\right)}_i)}^2+$

$\mathrm{\λ}\underset{i=2}{\overset{N-1}{\mathrm{\Σ}}}{\left\{\right[\mathrm{\τ}{\left(m\right)}_{i+1}-\mathrm{\τ}{\left(m\right)}_i]-[\mathrm{\τ}{\left(m\right)}_i-\mathrm{\τ}{\left(m\right)}_{i-1}\left]\right\}}^2$

In the formula: the baseline model data of the m time required calculating of iteration of τ (m) expression, S (m-1) _iBe the spectral data of baseline correction after the m-1 time iteration, m is meant iteration the m time, i=1, and 2 ..., N, N representes data length, w (S (m-1) _i) once proofread and correct the spectrogram weight array that the back spectrogram calculates before being based on, as S (m-1) _iWhen being signaling point, w (S (m-1) _i)=0; As S (m-1) _iWhen being noise spot, w (S (m-1) _i)=1.

As shown in Figure 3, (a) original match NMR spectral data wherein; (b) continuous wavelet transform combines the moving window method to carry out baseline identification; (c) on the b basis, add common iteration threshold method and carry out broad peak identification; (d) method that this paper proposes has been adopted in baseline identification.

As shown in Figure 4, (a) original metabolism group NMR spectral data wherein; (b) utilize polynomial fitting method to carry out baseline correction; (c) utilize Whittaker filtering to carry out baseline correction; (d) utilize Hodrick-Prescott filtering to carry out baseline correction; (e) utilize the baseline correction method that adopts among the present invention.

Claims (6)

1. an automatic baseline correction method is characterized in that, may further comprise the steps:

Step 1, the raw data of utilizing Fourier transform and phase correction processing collected to arrive obtain spectral data;

Step 2, utilize continuous wavelet transform that spectral data is calculated, obtain the numerical derivative of spectrogram;

Step 3, utilize the narrow peak-to-peak signal in the numerical derivative identification spectrogram of moving window method and spectrogram, it is interval to obtain narrow peak-to-peak signal;

Step 4, utilize the broad peak signal in the iteration threshold method identification spectral data, obtain part broad peak signal spacing;

Step 5, according to part broad peak signal spacing, utilize the profile approximating method to simulate the profile of broad peak signal;

Step 6, with in the spectral data greater than the point of the profile maximal value 3% of broad peak signal in the step 4 all as the broad peak signaling point, thereby obtain complete broad peak signal spacing;

Step 7, spectral data is deducted the interval and complete broad peak signal spacing of narrow peak-to-peak signal, and to obtain the baseline of spectrogram interval;

Step 8, utilize the interval initializes weights array of the baseline that obtains of step 7, if the spectral data point is positioned at the signal spacing, then the weight array value is initialized as 0, if the spectral data point is positioned at the baseline interval, then the weight array value is initialized as 1;

Step 9, utilize weight array and filtering algorithm to calculate baseline model;

Step 10, utilize the baseline model in the step 9 the described spectral data of step 1 to be proofreaied and correct the spectral data after obtaining proofreading and correct;

Step 11, each spectrum peak in the spectral data after judge proofreading and correct one by one; If the appearance of negative fractional part thinks that then this spectrum peak has produced distortion in the positive spike; If positive fractional part occurred in the negative spike; Think that then this spectrum peak produces distortion, distort then execution in step 12, withdraw from the spectral data after calculating final baseline model and proofreading and correct if the spectrum peak does not produce distortion if the spectrum peak produces;

Step 12, spectrum peak in the step 11 is produced the most serious some setting of the distortion baseline point that is as the criterion;

The weight array that accurate baseline point in step 13, the step 12 is corresponding is set to 1 and return step 9 and recomputate baseline model.

2. a kind of automatic baseline correction method according to claim 1 is characterized in that, utilizes the moving window method may further comprise the steps in the described step 3:

Step 3.1, according to the spectral data derivative calculations noise level σ that obtains in the step 2 _Noise

Step 3.2, setting threshold are n * σ _Noise, wherein n is a parameter value;

The size of step 3.3, the threshold value relatively confirmed in height and the step 3.2 of moving window, if the height of moving window greater than threshold value, then the central point of moving window is positioned at narrow peak-to-peak signal interval; If the height of moving window is smaller or equal to threshold value, then the central point of moving window is positioned at the baseline interval.

3. a kind of automatic baseline correction method according to claim 1 is characterized in that the iteration threshold method may further comprise the steps in the described step 4:

Step 4.1, utilize spectral data to calculate iteration threshold, iteration threshold is based on formula MEAN+3*SDEV, and MEAN is the mean value of spectral data, and SDEV is the standard deviation of spectral data;

Step 4.2, spectral data and iteration threshold are compared,, then carry out step 4.3 if there be the data point bigger than iteration threshold in spectral data; If points all in the spectral data then stop iteration all less than iteration threshold, obtain all broad peak signals, thereby obtain part broad peak signal spacing;

Step 4.3, spectral data that the ratio iteration threshold that obtains in the step 4.2 is big be as the broad peak signaling point, than the little spectral data of iteration threshold as the spectral data in the step 4.1 and return step 4.1.

4. a kind of automatic baseline correction method according to claim 2 is characterized in that parameter value n is 3 in the described step 3.2, in the described step 3.3 length of moving window be whole spectral data width 0.2%.

5. a kind of automatic baseline correction method according to claim 1 is characterized in that, the profile match in the described step 5 is based on and minimizes penalty P:

$P=\underset{\mathrm{\Ω}}{\mathrm{\Σ}}P\left(\mathrm{\Ω}\right)$

Wherein: as E (Ω)-S (Ω)>=0, P (Ω)=(E (Ω)-S (Ω)) ²As E (Ω)-S (Ω)≤0, P (Ω)=(f * (E (Ω)-S (Ω))) ², E (Ω) is the broad peak signal that needs match, and S (Ω) is the spectrum peak-to-peak signal, and f is a profile adjustment parameter, and Ω is the spectrogram frequency coordinate.

6. a kind of automatic baseline correction method according to claim 1 is characterized in that the filtering algorithm in the described step 9 is based on minimizing self-defined objective function:

$F\left(m\right)=\underset{i=1}{\overset{N}{\mathrm{\Σ}}}w{\left(S{(m-1)}_i\right)\×({S(m-1)}_i-\mathrm{\τ}{\left(m\right)}_i)}^2+$

$\mathrm{\λ}\underset{i=2}{\overset{N-1}{\mathrm{\Σ}}}{\left\{\right[\mathrm{\τ}{\left(m\right)}_{i+1}-\mathrm{\τ}{\left(m\right)}_i]-[\mathrm{\τ}{\left(m\right)}_i-\mathrm{\τ}{\left(m\right)}_{i-1}\left]\right\}}^2$

In the formula: m is meant iteration the m time, i=1, and 2 ..., N, N representes data length, the baseline model data of the m time required calculating of iteration of τ (m) expression, S (m-1) _iBe the spectral data of baseline correction after the m-1 time iteration, w (S (m-1) _i) once proofread and correct the spectrogram weight array that the back spectrogram calculates before being based on, as S (m-1) _iWhen being signaling point, w (S (m-1) _i)=0; As S (m-1) _iWhen being noise spot, w (S (m-1) _i)=1.

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